Composition for oral use based on s-adenosylmethionine and a process for their preparation

ABSTRACT

The present invention relates to solid dietary and/or nutraceutic pharmaceutical compositions for oral use based on SAMe, or salts thereof, in combination with inositol and/or derivatives thereof and to a process for their preparation. The present invention relates to a method of stabilising a solid composition for oral use based on SAMe or salts thereof, making use of inositol and/or derivatives thereof with the addition of magnesium oxide. The present invention also relates to the use of SAMe, or salts thereof, in combination with inositol and/or derivatives thereof with the possible further addition of melatonine, St. John&#39;s Wort and/or lemon balm for the treatment of depressive states and/or panic syndromes.

S-adenosylmethionine (SAMe) is a physiological methyl donor which ispresent in every living organism and is used in enzymatictransmethylation reactions. Accordingly, this substance plays a role ofconsiderable biological importance and is used clinically mainly as anantidepressant.

However, it is known that S-adenosylmethionine is difficult to use as apharmaceutical and/or dietary substance due to the fact that it isextremely unstable at temperatures above 0° C. or in the presence ofmoisture.

Accordingly, formulations based on S-adenosylmethionine, if notformulated using particular procedures and specific measures, reflectthe aforementioned instability of the active component which has obviousadverse effects on the preservation and storage of the product, evenover limited periods of time.

U.S. Pat. No. 3,954,726 and U.S. Pat. No. 4,057,672 describe salts ofS-adenosylmethionine which are relatively stable up to 25° C. and 45°C., respectively. U.S. Pat. No. 4,465,672 furthermore describes stablesalts of S-adenosylmethionine with 5 moles of a sulphonic acid having apK below 2.5.

In said latter US patent specification, the process for the preparationof the product comprises preparing a concentrated aqueous solution of anuntreated SAMe salt, purifying said solution and eluting it with adilute aqueous solution of the preselected sulphonic acid, titrating theresulting eluate, concentrating it and lyophilising or spray-drying it.Owing to the high instability of SAMe and its derivatives, the use of anaqueous medium reveals the limits of such a process, which, even if ispossible to limit the residual moisture, is still inadequate due to thecharacteristics of the active component.

Up to now, there are no known methods for stabilising and preservingS-adenosylmethionine salts in solid oral formulations, in particular intablets. The only known concept is that the moisture and impurities mustbe strictly controlled, and the tablets must be protected by filmcoating.

Accordingly, there is now felt to be a need for indicating a simple andeconomical process, which allows the preparation of a product which isbased on SAMe and exhibits reduced hygroscopicity and thus increasedstability.

Surprisingly, it has been found that the addition of inositol and/orderivatives thereof gives improved stability and reduced hygroscopicityof the SAMe, favouring moreover a synergic calming and antidepressantaction.

Accordingly, the present invention relates to solid dietary and/ornutraceutic oral pharmaceutical compositions comprising SAMe, or saltsthereof, in combination with inositol and/or derivatives thereof andpharmaceutically acceptable excipients.

According to the present invention, “SAMe” is understood to mean eitherthe racemic mixture or the individual diastereomers(RS)-(+)-S-adenosyl-L-methionine [(RS)-(+)-SAMe)] and(SS)-(+)-S-adenosyl-L-methionine [(SS)-(+)-SAMe)], including mixturesdifferent from the racemic one.

In particular, the compositions according to the present inventioncontain SAMe, or salts thereof, in an amount of between 10 and 90% byweight, preferably between 10 and 50% by weight, relative to the weightof the composition, in combination with inositol and/or derivativesthereof in an amount of between 50 and 90% by weight, preferably between30 and 85% by weight, relative to the weight of the composition.

Preferably, said SAMe and/or salts thereof is S-adenosylmethioninepara-toluenesulphonate.

Preferably, said inositol and/or derivatives thereof is inositol on itsown, inositol 6-phosphate or a mixture thereof.

In addition, according to a preferred aspect, at least one of thepharmaceutically acceptable excipients of the present invention ismagnesium oxide.

Optionally, the compositions according to the present invention cancontain at least one other active component, preferably selected frommelatonine or a St John's Wort dry extract or essential oil and/or alemon balm dry extract or essential oil and/or other extracts oressential oils having a tranquilising pharmacological action

The compositions according to the present invention can be in the formof tablets, capsules, granules and/or powders. Preferably, thecompositions according to the present invention are in the form oftablets, more preferably simple, coated, film-coated, layered and/orgastroresistant tablets.

In the present invention, a simple tablet is understood to mean a tabletobtained by direct compression or by compression following granulationwithout coating; a coated tablet is understood to mean a tablet coatedwith non-gastroresistant substances; a film-coated tablet is understoodto mean a coated tablet covered subsequently with aqueous varnishes, inwhich the varnishes can have a gastroresistant action. A layered tabletis understood to mean a tablet with two or three layers, obtained in asuitable tablet compressing machine.

Therefore, the compositions according to the present invention can befilm-coated with aqueous varnishes, preferably selected from gum lac(Shellac™) and/or salts thereof, methacrylic acid, celluloseacetophthalates, titanium dioxide, talcum, triethyl citrate, PVP K30,riboflavin 6-phosphate, hydroxypropylcellulose,hydroxypropylmethyl-cellulose and/or mixtures thereof.

A gastroresistant tablet according to the present invention isunderstood to mean a tablet capable of passing the gastric barrierunaltered.

Said film-coating by means of varnishes, when effected with Shellac™salt s, cellulose acetophthalates and/or other coatings insoluble inacidic media, can make the compositions according to the inventionresistant when passing through the gastric barrier. The varnishaccording to the present invention can be present in an amount whichvaries from 2.0 to 8.0% by weight, relative to the composition.

During said film-coating with aqueous varnishes, a lemon balm oil or St.John's Wort oil can be added in an amount of between 0.01 and 0.2% byweight, calculated relative to the total weight of the tablet.

The compositions according to the present invention are about eighttimes less hygroscopic compared with the previously known compositionsbased on SAMe, as reported in Table 1 below.

TABLE 1 Known tablets Known tablets based on SAMe based on SAMeSAMe/Inositol SAMe/Inositol SAMe tablet SAMe tablet tablets tablets 200mg 200 mg (Example 1) (Example 1) KF % T = 0 KF % T = 24 h* KF % T = 0KF % T = 24 h* Batch 01 1.55 3.42 0.80 0.93 Batch 02 1.44 3.24 0.74 0.89Batch 03 1.47 3.14 0.72 0.89 Batch 04 1.56 3.42 0.73 0.94 Batch 05 1.613.09 0.81 1.04 at 40° C. and 75% of r.h. KF (moisture determination bythe Karl Fischer method) T = time

The compositions according to the present invention are preferablyintended for the treatment of depressive states and panic-relatedsyndromes.

Another object of the present invention is a process for the preparationtablets for oral use comprising SAMe, or salts thereof, in combinationwith inositol and/or derivatives thereof, which comprises the steps of:

a) mixing SAMe, or salts thereof, with pharmaceutically acceptableexcipients;b) pre-compression, followed by granulation, of the mixture obtained instep a);c) coating the granules obtained in step b) with hydrogenated fattyacids;d) mixing, pre-compression and granulation of inositol and/orderivatives thereof with pharmaceutically acceptable excipients;e) coating the granules obtained in step d) with hydrogenated fattyacids;f) mixing the granules obtained in steps c) and e) with pharmaceuticallyacceptable excipients;g) compression of the mixture obtained in step f), with the optionaladdition of sweeteners and/or aromatic substances;h) optionally coating the tablets obtained in step g) with hydrogenatedfatty acids;i) optionally film-coating in the aqueous phase the tablets obtained instep h).

The process according to the present invention is carried out in anenvironment in which the relative humidity is below 25% and thetemperature is maintained between 20 and 30° C., preferably at about 25°C.

The granulation according to the present invention is preferably carriedout in a vibrating granulator equipped with a perforated stainless steelplate with holes 1 to 2 mm in diameter.

SAMe, or salts thereof, is used in an amount varying between 10 and 90%by weight, relative to the weight of the composition, preferably between10 and 50% by weight.

In particular, the pharmaceutically acceptable excipients used in theprocess according to the invention are preferably selected frommagnesium oxide, anhydrous microcrystalline cellulose, hydrogenatedfatty acids, magnesium stearate, glyceryl behenate, hydrogenated palmoil and hydrogenated castor oil. More particularly, in step a), theactive component is preferably mixed with about 1.0 to about 10.0% byweight of magnesium oxide and/or about 1.0 to about 20.0% by weight ofmicrocrystalline cellulose and/or about 1.0 to about 30.0% by weight ofhydrogenated fatty acids and/or about 0.5 to about 5% by weight ofmagnesium stearate, calculated relative to the active component.

In step c), the coating by means of hydrogenated fatty acids,preferably, melted hydrogenated vegetable fatty acids, can take place byconventional processes known in this sector, such as, for example by aprocess comprising the steps of:

1) coating with melted hydrogenated fat, if desired with the addition ofsurfactants which are miscible in the oily liquid. The addition of themelt takes place continuously by means of a peristaltic pump, preferablyby means of an airless atomiser at a flow rate of between 50 and 2000g/min, preferably between 200 and 1000 g/min.

The temperature of the mass to be coated is between 20° and 60° C.,preferably between 35° and 55° C.

2) if desired, subsequently coating the granules with pH-dependentpulverulent substances using in each case the previously selected mixer.Such substances are added in an amount of between 2% and 10% by weight,preferably between 3% and 5%.

3) separating off, for example on a vibrating sieve, any agglomerateswhich may have formed during the coating.

In step d), inositol and/or derivatives thereof are preferably mixedwith glyceryl behenate and/or hydrogenated palm oil and/or hydrogenatedcastor oil and/or stearic acid contained in an amount of between about 2and about 30% by weight, calculated relative to inositol and/or saltsthereof and/or derivatives thereof. Optionally, in said step d) of theprocess according to the invention, at least one further activecomponent, preferably selected from melatonine, St. John's Wort dryextract and lemon balm dry extract and/or mixtures thereof, can be addedto the mixture.

In step e), the coating with hydrogenated fatty acids, preferably meltedhydrogenated vegetable fatty acids, can be carried out by conventionalprocesses, known in the sector, such as, for example, the process whichcomprises the same steps listed above in step c).

According to the present invention, the coating described in step h) canbe carried out with hydrogenated fatty acids, preferably meltedhydrogenated vegetable fatty acids, in an amount of between about 0.5and about 2.5% by weight, relative to the weight of the composition.

Said step h) of the process according to the present invention allowsabout a two-fold reduction of the hygroscopicity of the tablets obtainedin g), resulting in significant advantages in the optional subsequentstep of film-coating in the aqueous phase.

The film-coating in the aqueous phase (step i) can be carried out with asubstance or varnish preferably selected from gum lac and/or saltsthereof (Shellac™), methacrylic acid, cellulose acetophthalates,titanium dioxide, talcum, triethyl citrate, PVP K30, riboflavin6-phosphate, hydroxypropylcellulose, hydroxypropylmethylcellulose and/ormixtures thereof.

In particular, said film-coating can be carried out with substancespreferably selected from gum lac (Shellac™) and/or salts thereof.

It is possible to add, to the varnish, lemon balm oil and/or St. John'sWort oil in an amount which varies between 0.01 and 0.2% by weight,relative to the total weight of the composition.

Another object of the present invention is the use of SAMe, or saltsthereof, in combination with inositol and/or derivatives thereof for thepreparation of dietary and/or nutraceutic pharmaceutical compositionsfor the treatment of depressive states and/or panic-related syndromes.

Yet another object of the present invention is a method of stabilisingsolid compositions for oral use based on SAMe or salts thereof, whichcomprises using inositol and/or derivatives thereof in the previouslymentioned percentages.

EXAMPLES Example 1 Tablets Containing 100 Mg of SAMe Ion/TabletComposition Based on SAMe Sulphate P-Toluenesulphonate/Inositol

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 1000.00 mg C.Magnesium oxide 50.00 mg D. Glyceryl behenate (Compritol-e-ato ®) 100.00mg E. Anhydrous microcrystalline cellulose 70.00 mg F. Magnesiumstearate 10.00 mg Total weight of the core 1445.00 mg G. Hydrogenatedvegetable fatty acids 8.00 mg H. Water-soluble Shellac ® 30.00 mg I. PVPK 30 6.0 mg L. Titanium dioxide 5.00 mg M. Talcum 10.00 mg N. Triethylcitrate 5.00 mg O. Riblofavin 6-phosphate 0.050 mg Total weight of thetablet 1509.05 mg

1.1. Mixing

The working environment is conditioned to a temperature of 25° C. and toa relative humidity value of about 25% of r.h. This is followed bytransferring A, C, E and 50% of F in the amounts listed above to themixer and stirring the resulting mixture for about 30 minutes. Uponcompletion of this operation, the resulting mixture is transferred todry containers with constant control of humidity and temperature.

1.2. Pre-Compression

The mixture is then pre-compressed in a Ronchi AM rotary tablettingmachine equipped with 18 round 25.0 mm punches. The hardness of thetablets produced must be regulated in such as to produce subsequently agranular product with good rheological properties.

1.3 Granulation

The tablets produced during the first processing stage are granulated on500-1200 μm meshes in each case in an environment with controlledhumidity.

1.4 Coating

The granules obtained in step 1.3 are covered with a coating of meltedhydrogenated vegetable fatty acids to give the granular product A.

1.5 Coating of Inositol

Inositol is granulated by pre-compression with 50% of the magnesiumstearate remaining from step 1.1 and then coated with meltedhydrogenated vegetable fatty acids to give the granules B.

1.6 Mixing

The granular products A and B are transferred to the mixer in theamounts listed above with the addition of microcrystalline cellulose andhalf of the magnesium stearate (F), and the resulting mixture is stirredfor about 30 minutes. Upon completion of said operation, the resultingmixture is transferred to dry containers.

1.7 Compression

The final compression of the granular products is performed by means ofa Ronchi AM rotary tabletting machine equipped in each case with 18oblong 21.0×9.8 mm punches, while regulating the weight to 1445mg/tablet and the compression force to at least 20 kp. The tabletsproduced have a hardness of between 16 and 22 kp.

Friability: ≦1.0%; Disaggregation time: ≦15 minutes (measured by themethodology described in U.S.P. XXIV ed.)

Moisture by K.F. ≦2.0%

Variation of the average weight: 1372.7-1517.2 mgStandard processing yield (ratio of the weight of the cores produced instage 1.7 to the overall weight of the initially weighed startingmaterials): 97%.

The stability tests on the uncoated tablets were only carried out at 40°C. and 75% of r.h. over a period of six months and for a single batchsince they were not finished products. The samples were kept in alu/alublister packs.

TABLE 2 Batch 055 - cores containing 100 mg of SAMe ion/tablet(qualitative/quantitative composition as in Example 1) Moisture in %MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 055 1.11 0.23 0.65107.01 (20/0) 055A 1.02 0.65 1.34 105.58 (40/1) 055B 1.03 0.95 1.67105.02 (40/3) 055C 1.05 1.45 2.32 104.23 (40/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

The data in Table 2 show that the tablets have optimum stability.

1.8: Coating of the Tablets

The tablets resulting from the preceding processing stages are coated ina drum mixer with a mixture of hydrogenated fatty acids (8.0 mg/tablet).The hydrogenated fatty acid obtained in the melting step at 70° C. ispoured into a 2-litre glass vessel, and the temperature of the mixtureis brought to about 75° C., resulting in a homogeneous melt.

After the drum mixer has been preheated to about 65° C., about 250 kg oftablets are introduced and allowed to heat up to 60° C. This is followedby protection of the cores performed by pouring the previously preparedmelt onto the moving tablets. The cores thus treated are left again at60° C. for about 3 minutes, until the drum of the drum mixer iscompletely free of the wax layer.

1.9: Film-Coating of the Tablets

Shellac™ and PVP are dissolved in a container of suitable size at 50° C.to give a 20% (w/v) strength solution, and the triethyl citrate isslowly added with constant stirring.

In a different steel container, again equipped with a stirrer, thetalcum, titanium dioxide and riboflavin 6-phosphate are dispersed in 4.0l of deionised water. The resulting suspension is poured into theShellac™ solution, the container is rinsed with about 1.0 l of deionisedwater, and the resulting mixture is diluted subsequently with another4.0 l of deionised water.

During the first coating stage, the temperature of the cores ismaintained at 54° C. for about 40 minutes, and subsequently and atregular intervals, is lowered until the value of 50° C. is reached inthe final stage.

Once the coating of the protected cores is completed, they are allowedto dry for another 10 minutes while maintaining them at 50° C. Finally,the temperature is allowed to drop to 45-46° C., at which point theemptying of the drum mixer can be started, taking care that the tabletsare kept in suitable covers impermeable to moisture. On the tablets thusobtained, no increase in the percentage moisture content was observed.Moreover, all checks stipulated in the quality specifications werecarried out on the tablets.

Example 2 Tablets Containing 100 Mg of SAMe Ion/Tablet Composition Basedon SAMe Sulphate P-Toluenesulphonate/Inositol/Inositol 6-Phosphate

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 600.00 mg C.Inositol 6-phosphate 400.00 mg C. Magnesium oxide 50.00 mg D. Glycerylbehenate (Compritol-e-ato ®) 100.00 mg E. Anhydrous microcrystallinecellulose 70.00 mg F. Magnesium stearate 10.00 mg Total weight of thecore 1445.00 mg G. Hydrogenated fatty acids 8.00 mg H. Water-solubleShellac ® 30.00 mg I. PVP K 30 6.0 mg L. Titanium dioxide 5.00 mg M.Talcum 10.00 mg N. Triethyl citrate 5.00 mg O. Riblofavin 6-phosphate0.050 mg Total weight of the tablet 1509.05 mg

The amounts refer to the preparation of a standard industrial batch of250.00 kg of tablets.

The tablets were prepared according to the procedure described inExample 1 using the components and amounts listed above.

Example 3 Tablets Containing 100 Mg of SAMe Ion/Tablet Composition Basedon SAMe Sulphate P-Toluenesulphonate/Inositol/Inositol 6-Phosphate

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 600.00 mg C.Inositol 6-phosphate 400.00 mg D. Magnesium oxide 50.00 mg E. Glycerylbehenate (Compritol-e-ato ®) 100.00 mg F. Anhydrous microcrystallinecellulose 70.00 mg G.Magnesium stearate 10.00 mg H. Mannitol 100.00 mgI. Hydrogenated fatty acids 200.00 mg I. Aromas 0.01 mg L. Sweeteners0.01 mg Total weight of the core 1745.02 mg

The amounts refer to the preparation of a standard industrial batch of250.00 kg of tablets.

The tablets were prepared according to the procedure described inExample 1 using the components and amounts listed above.

TABLE 3 Batch 056 - cores containing 100 mg of SAMe ion/tablet Moisturein % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 056 1.00 0.350.46 104.11 (20/0) 056A 1.02 0.66 1.82 103.56 (40/1) 056B 1.04 0.85 2.45100.23 (40/3) 056C 1.32 1.34 3.43 95.56 (40/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

The data in Table 3 show that the tablets have optimum stability.

Example 4 Tablets Containing 100 Mg of SAMe Ion/Tablet Composition Basedon SAMe Sulphate P-Toluenesulphonate/Inositol

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 1000.00 mg C.Magnesium oxide 50.00 mg D. Glyceryl behenate (Compritol-e-ato ®) 100.00mg E. Anhydrous microcrystalline cellulose 70.00 mg F. Magnesiumstearate 10.00 mg G. Mannitol 100.00 mg H. Hydrogenated fatty acids200.00 mg I. Aromas 0.01 mg L. Sweeteners 0.01 mg Total weight of thecore 1745.02 mg

The amounts refer to the preparation of a standard industrial batch of250.00 kg of tablets.

The tablets were prepared according to the procedure described inExample 1 using the components and amounts listed above.

Example 5 Tablets Containing 100 Mg of SAMe Ion/Tablet+St. John's WortExtract

Composition Based on SAMe Sulphate P-Toluenesulphonate/Inositol/St.John's Wort Extract

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 1000.00 mg C.St. John's Wort extract 100.00 mg D. Magnesium oxide 50.00 mg E.Glyceryl behenate (Compritol-e-ato ®) 100.00 mg F. Anhydrousmicrocrystalline cellulose 70.00 mg G. Magnesium stearate 10.00 mg H.Mannitol 100.00 mg I. Hydrogenated fatty acids 200.00 mg L. Aromas 0.01mg M. Sweeteners 0.01 mg Total weight of the core 1845.02 mg

The amounts refer to the preparation of a standard industrial batch of250.00 kg of tablets.

The tablets were prepared according to the procedure described inExample 1 using the components and amounts listed above.

TABLE 4 Batch 057 cores containing 100 mg of SAMe ion/tablet MoistureBatch in % AD² MTAD³ SAMe⁴ Hypericin (T/t)¹ (K.F.) (%) (%) mg/tablet mg057   1.22 0.33 0.12 112.11 3.06 (20/0) 057A 1.12 0.54 0.45 102.23 2.94(40/1) 057B 1.13 0.77 1.66 98.89 2.86 (40/3) 057C 1.07 1.45 2.99 95.442.77 (40/6) ¹Temperature (° C.)/time (months); ²adenosine;³methylthioadenosine; ⁴SAMe sulphate p-toluenesulphonate (mg/tablet).

The data from table 4 show that the tablets have optimum stability.

Example 6 Tablets Containing 100 Mg of SAMe Ion/Tablet+St. John's WortExtract+inositol 6-phosphate

Composition Based on SAMe Sulphate P-Toluenesulphonate/Inositol/Inositol6-Phosphate/St. John's Wort Extract

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 600.00 mg C.Inositol 6-phosphate 400.00 mg D. St. John's Wort extract 100.00 mg E.Magnesium oxide 50.00 mg F. Glyceryl behenate(Compritol-e-ato ®) 100.00mg G. Anhydrous microcrystalline cellulose 70.00 mg H. Magnesiumstearate 10.00 mg I. Mannitol 100.00 mg L. Hydrogenated fatty acids200.00 mg M. Aromas 0.01 mg N. Sweeteners 0.01 mg Total weight of thecore 1845.02 mg

The amounts refer to the preparation of a standard industrial batch of250.00 kg of tablets.

The tablets were prepared according to the procedure described inExample 1 using the components and amounts listed above.

TABLE 5 Batch 058 cores containing 100 mg of ion/tablet (EX. 5) MoistureBatch in % AD² MTAD³ SAMe⁴ Hypericin Inositol 6- (T/t)¹ (K.F.) (%) (%)mg/tablet mg phosphate 058 1.31 0.35 0.62 108.14 2.99 399.5 (20/0) 058A1.18 0.64 0.85 100.23 2.7 398.6 (40/1) 058B 1.23 0.87 2.36 95.89 2.66397.6 (40/3) 058C 1.24 1.99 3.79 93.54 2.70 395.5 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet).

The data in Table 5 show that the tablets have optimum stability.

Example 7 Tablets Containing 100 Mg of SAMeIon/Tablet+Melatonine+Inositolo Composition Based on SAMe SulphateP-Toluenesulphonate/Inositolo/Melatonine

A. SAMe sulphate p-toluenesulphonate 215.00 mg B. Inositol 600.00 mg C.Melatonine 400.00 mg D. Magnesium oxide 100.00 mg E. Glycerylbehenate(Compritol-e-ato ®) 50.00 mg F. Anhydrous microcrystallinecellulose 100.00 mg G. Magnesium stearate 70.00 mg H. Xylitol 10.00 mgI. Hydrogenated fatty acids 100.00 mg L. Aromas 200.00 mg M. Sweeteners0.01 mg 0.01 mg Total weight of the core 1845.02 mg

The amounts refer to the preparation of a standard industrial batch of250.00 kg of tablets.

The tablets were prepared according to the procedure described inExample 1 using the components and amounts listed above.

Experimental Section Stability Tests on the Finished Product

Both the stability at 40° C. 75% of r.h. (STRESS TEST) and the long-termstability at ambient temperature (SHELF LIFE) of the compositions fromExamples 1, 2, 3, 4, 5, 6 obtainable by the process according to theinvention were determined on the basis of variations in the appearance(mostly colour variations), the content (mg/tablet) in SAMe sulphatep-toluenesulphonate and other active components, the increase indegradation impurities and the moisture (K. F.); the presence of anydegradation products substantially identifiable in adenosine andmethylthioadenosine, expressed in percent, relative to mg of SAMesulphate p-toluenesulphonate per tablet, was furthermore controlled byHPLC.

Stress Test

The tablets were packaged in closed and sealed glass vials, in order toreproduce the final packaging conditions (in general, alu/alu blisterpacks).

The samples thus prepared were kept for six months in an oven(Kottermann), thermostatted at a temperature of 40±2° C. and 75% of r.h.

Nine samples from three different batches were used for the 100 mgtablets (Ex. 1, 2, 3, 4, 5, 6) where each sample, in each batch, wassampled after 0, 1, 3 and 6 months.

The results of the stress test are shown in the tables below (6-23).

TABLE 6 Batch 059A - tablets containing 100 mg of ion/tablet (EX. 1)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 059 1.380.31 0.41 112.42 (20/0) 059A 1.26 1.14 1.75 111.19 (40/1) 059B 1.54 1.952.18 109.12 (40/3) 059C 1.46 2.01 2.61 105.67 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 7 Batch 060 - tablets containing 100 mg of ion/tablet (EX. 1)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 060 1.560.31 0.27 113.93 (20/0) 060A 1.61 1.05 1.89 109.78 (40/1) 060B 1.49 1.722.37 105.37 (40/3) 060C 1.41 1.84 2.53 103.67 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 8 Batch 061 - tablets containing 100 mg of ion/tablet (EX. 1)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 061 1.300.47 0.42 113.43 (20/0) 061A 1.56 1.04 1.00 109.19 (40/1) 061B 1.45 1.782.36 107.36 (40/3) 061C 1.53 2.32 2.20 105.43 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 9 Batch 062 - tablets containing 100 mg of ion/tablet (EX. 2)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 062 1.390.42 0.38 111.60 (20/0) 062A 1.58 1.81 1.15 110.9 (40/1) 062B 1.23 1.782.05 108.62 (40/3) 062C 1.60 2.03 2.41 106.51 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 10 Batch 063 tablets containing 100 mg of ion/tablet (EX. 2)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 063 1.110.34 0.56 116.22 (20/0) 063 1.18 1.21 1.23 113.43 (40/1) 063 1.08 1.631.45 109.16 (40/3) 063 1.21 2.01 2.39 107.21 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 11 Batch 064 - tablets containing 100 mg of ion/tablet (EX. 2)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 064 1.320.29 0.53 111.20 (20/0) 064A 1.23 1.04 1.01 108.30 (40/1) 064B 1.17 1.231.36 106.25 (40/3) 064C 1.15 1.89 2.45 105.20 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 12 Batch 065 - tablets containing 100 mg of ion/tablet (EX. 3)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 065 1.310.32 0.24 112.60 (20/0) 065A 1.28 1.23 1.02 111.9 (40/1) 065B 1.43 1.541.45 108.62 (40/3) 065C 1.23 1.93 2.02 107.45 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 13 Batch 066 tablets containing 100 mg of ion/tablet (EX. 3)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 066 1.110.34 0.46 113.22 (20/0) 066 1.13 1.21 1.01 111.43 (40/1) 066 1.18 1.561.35 109.45 (40/3) 066 1.22 2.11 1.99 107.98 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 14 Batch 067 - tablets containing 100 mg of ion/tablet (EX. 3)Moisture in % MTAD³ Batch (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 067 1.230.29 0.32 110.20 (20/0) 067A 1.24 1.14 0.95 107.30 (40/1) 067B 1.17 1.451.34 106.25 (40/3) 067C 1.35 1.99 1.78 104.43 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 15 Batch 068 - tablets containing 100 mg of ion/tablet (EX. 4)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 068 1.330.32 0.42 109.45 (20/0) 068A 1.26 1.01 0.76 108.9 (40/1) 068B 1.65 1.441.35 10562 (40/3) 068C 1.46 1.50 1.87 103.87 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 16 Batch 069 tablets containing 100 mg of ion/tablet (EX. 4) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 069 1.33 0.370.39 107.05 (20/0) 069A 1.44 1.02 0.99 106.43 (40/1) 069B 1.53 1.67 1.54105.69 (40/3) 069C 1.50 2.43 1.97 103.45 (40/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 17 Batch 070 - tablets containing 100 mg of ion/tablet (EX. 4)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 070 1.450.20 0.42 110.34 (20/0) 070A 1.65 1.34 0.94 108.54 (40/1) 070B 1.53 1.751.39 106.34 (40/3) 070C 1.49 2.09 1.98 104.96 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 18 Batch 071 - tablets containing 100 mg of ion/tablet (EX. 5)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 071 1.440.39 0.53 112.45 (20/0) 071A 1.46 1.11 1.46 110.34 (40/1) 071B 1.63 1.451.65 107.65 (40/3) 071C 1.56 1.80 2.37 105.99 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 19 Batch 072 tablets containing 100 mg of ion/tablet (EX. 5) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 072 1.61 0.290.41 109.56 (20/0) 072A 1.76 0.76 0.79 107.67 (40/1) 072B 1.53 1.37 1.44105.69 (40/3) 072C 1.61 2.02 1.85 103.69 (40/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 20 Batch 073 - tablets containing 100 mg of ion/tablet (EX. 5)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 073 1.450.23 0.34 110.33 (20/0) 073A 1.62 1.54 0.92 108.52 (40/1) 073B 1.54 1.851.49 105.74 (40/3) 073C 1.67 2.39 1.88 103.95 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 21 Batch 074 - tablets containing 100 mg of ion/tablet (EX. 6)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 074 1.440.39 0.34 111.23 (20/0) 074A 1.66 1.41 0.87 110.34 (40/1) 074B 1.69 1.751.45 107.23 (40/3) 074C 1.54 1.89 2.12 104.59 (40/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 22 Batch 075 tablets containing 100 mg of ion/tablet (EX. 6) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 075 1.46 0.430.45 109.56 (20/0) 075A 1.66 0.83 0.98 107.67 (40/1) 075B 1.59 1.47 1.54105.69 (40/3) 075C 1.63 2.32 1.99 103.69 (40/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 23 Batch 076 - tablets containing 100 mg of ion/tablet (EX. 6)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 076 1.560.27 0.34 114.63 (20/0) 0763A 1.62 1.64 0.87 112.52 (40/1) 076B 1.591.89 1.67 110.54 (40/3) 076C 1.69 2.39 2.28 108.56 (40/6) ¹Temperature(° C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

From the stability data at 40° C. and 75% of r.h. (stress test), it canbe seen that after six months all batches tested were subject to adegradation of about 5% both in terms of SAMe and the other activecomponents.

Shelf Life

The tablets were packaged in closed and sealed glass vials, in order toreproduce the final packaging conditions (in general, alu/alu blisterpacks).

The samples were selected using the same method and amounts describedfor the stress test and kept in a thermostatted environment at atemperature of 25±2° C. and a humidity of 60% of r.h.

Nine samples from three different batches were used for the 100 mgtablets (Ex. 1, 2, 3, 4, 5, 6) where each sample, in each batch, wassampled after 0, 3, 6, and 12 months.

The results of the shelf life test are shown in the tables below(24-41).

TABLE 24 Batch 077A - tablets containing 100 mg of ion/tablet (EX. 1)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 077 1.380.31 0.41 112.42 (20/0) 077A 1.29 0.54 1.45 112.19 (25/3) 077B 1.44 0.642.11 111.54 (25/6) 077C 1.48 0.89 2.21 110.57 (25/12) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 25 Batch 078 - tablets containing 100 mg of ion/tablet (EX. 1)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 078 1.560.31 0.27 113.93 (20/0) 078A 1.41 0.55 0.49 113.78 (25/1) 078B 1.46 0.720.77 112.37 (25/3) 078C 1.51 0.84 0.93 111.67 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet)

TABLE 26 Batch 079 - tablets containing 100 mg of ion/tablet (EX. 1)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 079 1.300.47 0.42 113.43 (20/0) 079A 1.66 0.64 0.78 111.99 (25/1) 079B 1.55 0.780.89 111.09 (25/3) 079C 1.58 1.32 1.20 110.32 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 27 Batch 080 - tablets containing 100 mg of ion/tablet (EX. 2)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 080 1.390.42 0.38 111.60 (20/0) 080A 1.58 0.71 0.55 111.79 (25/1) 080B 1.23 1.020.78 109.92 (25/3) 080C 1.60 1.33 0.91 109.51 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 28 Batch 081 tablets containing 100 mg of ion/tablet (EX. 2) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 081 1.11 0.340.56 116.22 (20/0) 081 1.28 0.41 0.55 115.43 (25/1) 081 1.38 0.63 0.85115.00 (25/3) 081 1.31 0.81 1.39 114.21 (25/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 29 Batch 082 - tablets containing 100 mg of ion/tablet (EX. 2)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 082 1.320.29 0.53 111.20 (20/0) 082A 1.33 0.44 0.61 110.30 (25/1) 082B 1.37 0.630.76 110.25 250/3) 082C 1.45 0.89 1.25 109.48 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 30 Batch 083 - tablets containing 100 mg of ion/tablet (EX. 3)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 083 1.310.32 0.24 112.60 (20/0) 083A 1.48 0.34 0.42 110.42 (25/1) 083B 1.42 0.540.45 111.12 (25/3) 083C 1.53 0.83 1.02 110.21 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 31 Batch 084 tablets containing 100 mg of ion/tablet (EX. 3) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 084 1.11 0.340.46 113.22 (20/0) 084A 1.33 0.41 0.66 112.43 (25/1) 084B 1.28 0.56 0.85111.45 (25/3) 084C 1.12 0.89 0.99 111.28 (25/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 32 Batch 085 - tablets containing 100 mg of ion/tablet (EX. 3)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 085 1.230.29 0.32 110.20 (20/0) 085A 1.14 0.34 0.55 109.50 (25/1) 085B 1.17 0.450.74 108.25 (25/3) 085C 1.15 0.69 0.79 107.34 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 33 Batch 086 - tablets containing 100 mg of ion/tablet (EX. 4)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 086 1.330.32 0.42 109.45 (20/0) 086A 1.21 0.44 0.76 108.44 (25/1) 086B 1.25 0.440.88 108.32 (25/3) 086C 1.16 0.50 0.98 107.34 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 34 Batch 087 tablets containing 100 mg of ion/tablet (EX. 4) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 087 1.33 0.370.39 107.05 (20/0) 087A 1.12 0.32 0.59 107.43 (25/1) 087B 1.13 0.43 0.54106.69 (25/3) 087C 1.23 0.73 0.93 106.11 (25/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 35 Batch 088 - tablets containing 100 mg of ion/tablet (EX. 4)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 088 1.450.20 0.42 110.34 (20/0) 088A 1.35 0.34 0.64 110.54 (25/1) 088B 1.23 0.650.59 109.34 (25/3) 088C 1.39 0.69 0.58 108.56 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 36 Batch 089 - tablets containing 100 mg of ion/tablet (EX. 5)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 089 1.440.39 0.53 112.45 (0/0) 089A 1.22 0.53 0.66 112.33 (25/1) 089B 1.31 0.650.73 111.65 (25/3) 089C 1.22 0.84 0.95 110.59 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 37 Batch 090 tablets containing 100 mg of ion/tablet (EX. 5) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 090 1.61 0.290.41 109.56 (20/0) 090A 1.33 0.56 0.59 108.67 (25/1) 090B 1.45 0.77 0.74107.69 (25/3) 090C 1.41 0.92 0.85 106.44 (25/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 38 Batch 091 - tablets containing 100 mg of ion/tablet (EX. 5)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 091 1.450.23 0.34 110.33 (20/0) 091A 1.42 0.54 0.52 109.52 (25/1) 091B 1.34 0.850.49 108.74 (25/3) 091C 1.47 1.39 0.88 106.95 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 39 Batch 092 - tablets containing 100 mg of ion/tablet (EX. 6)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 092 1.440.39 0.34 111.23 (20/0) 092A 1.36 0.41 0.67 110.11 (25/1) 092B 1.49 0.550.75 109.44 (25/3) 092C 1.23 0.89 1.12 109.49 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 40 Batch 093 tablets containing 100 mg of ion/tablet (EX. 6) BatchMoisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 093 1.46 0.430.45 109.56 (20/0) 093A 1.32 0.53 0.58 108.99 (25/1) 093B 1.21 0.67 0.54108.69 (25/3) 093C 1.23 1.12 0.89 107.69 (25/6) ¹Temperature (° C.)/time(months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

TABLE 41 Batch 094 - tablets containing 100 mg of ion/tablet (EX. 6)Batch Moisture in % MTAD³ (T/t)¹ (K. Fischer) AD² (%) (%) SAMe⁴ 094 1.560.27 0.34 114.63 (20/0) 094A 1.44 0.64 0.87 113.52 (25/1) 076B 1.34 0.871.67 112.54 (25/3) 094C 1.32 1.39 2.28 112.76 (25/6) ¹Temperature (°C.)/time (months); ²adenosine; ³methylthioadenosine; ⁴SAMe sulphatep-toluenesulphonate (mg/tablet);

From the stability data at 25° C. and 60% of r.h. (shelf life), it canbe seen that after twelve months all batches tested were subject to avery low degradation in terms of SAMe.

1. Dietary and/or nutraceutic oral pharmaceutical composition comprisingS-adenosylmethionine para-toluenesulphonate in combination with inositoland/or derivatives thereof and pharmaceutically acceptable excipients.2. (canceled)
 3. Composition according to claim 1, in which saidinositol and/or derivatives is inositol on its own, inositol-1-phosphateor a mixture thereof.
 4. Composition according to claim 1, in which theS-adenosylmethionine para-toluenesulphonate is contained in an amountwhich varies from about 10 to about 90% by weight, relative to theweight of the composition.
 5. Composition according to claim 4, in whichthe S-adenosylmethionine para-toluenesulphonate is contained in anamount which varies from about 10 to 50% by weight, relative to theweight of the composition.
 6. Composition according to claim 1, in whichthe inositol and/or derivatives thereof is contained in an amount whichvaries from about 50 to about 90% by weight, relative to the weight ofthe composition.
 7. Composition according to claim 6, in which theinositol and/or derivatives thereof is contained in an amount whichvaries from about 30 to about 85% by weight, relative to the weight ofthe composition.
 8. Composition according to claim 1, comprising atleast one other active component, preferably selected from melatonine,St. John's Wort dry extract and lemon balm dry extract or mixturesthereof.
 9. Composition according to claim 1, in which at least one ofthe pharmaceutically acceptable excipients is magnesium oxide. 10.Composition according to claim 1, in the form of a tablet, capsule,granule or powder.
 11. Composition according to claim 10, in the form ofa tablet, wherein the tablet is a simple, coated, film-coated, layeredand/or gastroresistant tablet.
 12. Composition according to claim 10, inthe form of a tablet, wherein the tablet is a gastroresistant tablet.13. Process for the preparation of a tablet according to claim 1, whichcomprises the steps of: a) mixing the SAMe or salts thereof withpharmaceutically acceptable excipients; b) pre-compression, followed bygranulation, of the mixture obtained in step a); c) coating thegranulated product obtained in step b) with hydrogenated fatty acids; d)mixing, pre-compression and granulation of the inositol and/orderivatives thereof with pharmaceutically acceptable excipients; e)coating of the granulated products obtained in step d) with hydrogenatedfatty acids; f) mixing the granulated products obtained in steps c) ande) with pharmaceutically acceptable excipients; g) compressing themixture obtained in step f) with the optional addition of sweeteners andaromas; h) optionally coating the tablets obtained in step g) withhydrogenated fatty acids; and i) optionally film-coating in the aqueousphase the tablets obtained in step h).
 14. (canceled)
 15. Processaccording to claim 13, in which said inositol and/or derivatives thereofis inositol on its own, inositol-1-phosphate or a mixture thereof. 16.Process according to claim 13, in which the relative humidity is belowabout 25% and the temperature is maintained between about 20° C. and 30°C., in particular at about 25° C.
 17. Process according to claim 13, inwhich in step d) it is possible to add, to the mixture, at least oneother active component, preferably selected from melatonine, St. John'sWort dry extract and lemon balm dry extract and/or mixtures thereof. 18.Process according to claim 13, in which the coating carried out in steph) is effected with hydrogenated fatty acids in an amount of between 0.5and 2.5% by weight, relative to the weight of the composition. 19.Process according to claim 13, in which the film-coating in the aqueousphase carried out in step i) is effected with a varnish, preferablyselected from rubber varnish and/or salts thereof (Shellac™),methacrylic acid, cellulose acetophthalates, titanium dioxide, talcum,triethyl citrate, PVP K30, riboflavin 6-phosphate,hydroxypropylcellulose, hydroxypropylmethyl-cellulose and/or mixturesthereof.
 20. Process according to claim 19, in which the varnish iscontained in an amount ranging from about 2.0 to about 8.0% by weight,relative to the composition.
 21. Process according to claim 13, in whichin step i) it is possible to optionally add lemon balm and/or St. John'sWort oil in an amount which varies from about 0.01 to about 0.2% byweight, relative to the total composition.
 22. Dietary and/ornutraceutic pharmaceutical compositions obtainable by means of theprocess according to any one of claims 13, 15-21.
 23. Method for thetreatment of depressive states and panic syndromes which comprises theadministration of SAMe, or salts thereof, in combination with inositoland/or derivatives thereof to a patient in such a need.
 24. (canceled)25. Method according to claim 23, in which said inositol and/orderivatives thereof is inositol on its own, inositol-1-phosphate or amixture thereof.
 26. Method of stabilising a solid dietary and/ornutraceutic pharmaceutical composition based on SAMe or salts thereof,which comprises using inositol and/or derivatives thereof.
 27. Methodaccording to claim 26, in which the SAMe or salts thereof is containedin an amount of between about 10 and about 90% by weight, calculatedrelative to the weight of the composition.
 28. Method according to claim27, in which the SAMe or salts thereof is contained in an amount ofbetween about 10 and about 50% by weight, calculated relative to theweight of the composition.
 29. Method according to claim 26, in whichthe inositol and/or derivatives thereof is contained in an amount whichvaries from about 50 to about 90% by weight, relative to the weight ofthe composition.
 30. Method according to claim 29, in which the inositoland/or derivatives thereof is contained in an amount which varies fromabout 50 to about 85% by weight, relative to the weight of thecomposition.
 31. Process according to claim 13, wherein said SAMe isS-adenosylmethionine para-toluenesulphonate.
 32. Method according toclaim 23, wherein said SAMe is S-adenosylmethioninepara-toluenesulphonate.